Computer based versatile method for identifying protein coding DNA sequences useful as drug targets

ABSTRACT

The present invention relates to a versatile method of identifying protein coding DNA sequences (genes) useful as drug targets in a genome using specially developed software GeneDecipher, said method comprising steps of generating peptide libraries from the known genomes with peptide of length ‘N’ computationally arranged in an alphabetical order, artificially translating the test genome to obtain a polypeptide corresponding to each reading frame, converting each polypeptide sequence into an alphanumeric sequence one corresponding to each reading frame on the basis of overlappings with the peptide libraries, training Artificial Neural Network (ANN) with sigmoidal learning function to the alphanumeric sequence, deciphering the protein coding regions in the test genome, thus, identifying longer streches of peptides mapping to large number of known genes and their corresponding proteins and lastly, a method of the management of the diseases caused by the pathogenic organisms comprising a step of evaluation of the proposed drug candidate by inhibiting the functioning of one or more proteins identified by the steps of the invention.

FIELD OF THE PRESENT INVENTION

This invention relates to a versatile method for identifying protein coding DNA sequences useful as drug targets. More particularly this invention relates to a method for identification of novel genes in genome sequence data of various organisms, useful as potential drug targets. This invention further provides a method for assignment of function to hypothetical Open Reading Frames (proteins) of unknown function through exact amino acid sequence identity signature.

Emergence of high throughput sequencing technologies has necessitated identification of novel protein coding DNA sequences (genes) in newly sequenced genomes. The invention provides a novel method of converting DNA sequence to alphanumeric sequence by the use of peptide library. The invention also provides a method for use of artificial neural network (feed forward back propagation topology) with one input layer, one hidden layer with 30 neurons and one output layer for identification protein coding DNA sequences. The invention further provides a method for training of neural networks using sigmoid as a learning function with five parameters namely total score, mean, fraction of zeroes, maximum continuous non-zero stretch and variance for identification of protein coding DNA sequence.

BACKGROUND AND PRIOR ART REFERENCES OF THE PRESENT INVENTION

The most reliable way to identify a protein coding DNA sequence (gene) in a newly sequenced genome is to find a close homolog from other organisms (BLAST (Altschul, S. F et al., 1990) and FASTA (Pearson, W. R., 1995)). Four nucleotides in a DNA sequence are not randomly distributed. The statistical distribution of nucleotides within a coding region is significantly different from the non-coding (Bird, A., 1987). Methods based on Hidden Markov Models (HMM) have used these statistical properties most efficiently (Salzberg, S. L et al., 1998; Delcher, A. L et al., 1999; Lukashin, A. V. and Borodovsky, M., 1998) and are able to predict ˜97-98% of all the genes in a genome when compared with published annotations (Delcher, A. L et al., 1999). Using HMM, various algorithms like GeneMark, Glimmer etc. have been developed to predict genes in prokaryotes. Glimmer 2.0 is the most successful method among all existing methods (Delcher, A. L et al., 1999). However, Glimmer also predicts 7-20% additional genes (false positives).

Each gene prediction method has its own strengths and weaknesses (Mathe, C. et al., 2002). Since the prediction is usually dependent on the training set, shortcomings arise because statistics for a coding region vary across various genomes. Also, these methods are unable to efficiently predict genes small in length (<100 amino acids), because it's very difficult to detect these genes by similarity searches or by statistical analysis. The problem becomes more severe in case of horizontal gene transfer (Kehoe, M. A et al., 1996). In this case statistical distribution of the nucleotide sequence of these genes differs within a genome itself.

The said method of the invention is based upon the observation that the difference between total number of theoretically possible peptides of a given length and that which are actually observed in nature, increases drastically as this length of peptide increases. For example, only about 2% of the theoretically possible heptapeptides are observed in a pool of 56 completely sequenced prokaryotic genomes. At octapeptide level this number reduces to even less than 0.1%. Moreover, it is interesting to note that most of these peptides selected by nature are found only in the coding regions and very rarely in theoretically translated non-coding regions. This observation has prompted us to exploit this exclusivity of natural selection of peptides that are present in protein coding sequences to differentiate between coding and non-coding regions.

In principle, using longer peptides to score a query ORF is always preferable to using shorter ones (Salzberg, S. L. et al., 1998), but only if sufficient data is available to estimate statistical parameters required to train the prediction algorithm. In case we use peptides of length 8 or more amino acids, it is difficult to get sufficient data to estimate the training parameters. This is because likelihood of an octapeptide being shared between two polypeptides is less than that of a heptapeptide. So we consider the length of 7 amino acids as optimum for scoring of an ORF.

The novelty of the said method is that it works on the basis of protein coding sequences at amino acid, not at nucleotide sequence level. It is noteworthy that the method does not need an organism specific training set, which is an obvious advantage over other methods. Unlike other methods, GeneDecipher does not employ any landmarks like ribosome binding sites, promoter sequences, transcription start sites or codon usage biases to predict the coding genes and their start locations. In addition, this method overcomes the difficulties of gene prediction for smaller genomes (Chen, L et. al., 2003) like SARS-CoV. Other than gene prediction, this method can also be utilized for similarity searches for polypeptides, putative functional assignment to proteins (based on presence of the oligo-peptide motifs), and in phylogenetic domain analysis, indicating the generic-ness and versatility of the method.

Current computational methods like GeneMark.hmm (Lukashin and Borodovsky, 1998), Glimmer (Salzberg et al., 1998), etc. face difficulty in analyzing the small genomes such as of SARS. Methods based on Hidden Markov Models (HMM) require thousands of parameters for training. This makes these methods less suitable for analyzing smaller genomes. The problem compounds in the case of SARS-CoV genomes, which are about 30 kb length. Even the method most suitable for viral gene prediction till date ZCURVE_CoV (Chen et al., 2003) needs 33 parameters for training. GeneDecipher needs only 5 parameters and can analyze smaller genomes too. The applicants have trained the Artificial Neural Network on ecoli-k12 genome coding and non-coding regions (ORFs not reported as a gene). To predict protein coding genes using GeneDecipher on viral genomes no additional training is required. This is an obvious advantage of this method over other methods.

OBJECTS OF THE PRESENT INVENTION

The main object of the present invention is to provide a computer based method for predicting protein coding DNA sequences (genes) useful as drug targets.

Another main object of the present invention is to develop a versatile method of identifying genes using oligopeptides that are found to occur in the ORFs of other genomes using software GeneDecipher.

Still another object of the present invention is to develop a method applicable in the management of the diseases caused by the pathogenic organisms.

Still another object of the present invention is to develop a computer based system for performing the aforementioned methods.

Yet another object of the present invention is to develop a method useful for identification of novel protein coding DNA sequences useful as potential drug targets and can serve as drug screen for broad spectrum antibacterial as well as for specific diagnosis of infection. Still another object of the present invention is to identify strain specific or organism specific protein coding genes.

Yet another object of the method of invention is to identify protein coding DNA sequences (exons) in eukaryotic organisms.

Another object of the present invention is to assignment of function to hypothetical Open Reading Frames (proteins) of unknown function through exact amino acid sequence identity signature.

SUMMARY OF THE PRESENT INVENTION

The present invention relates to a versatile method of identifying genes using oligopeptides that are found to occur in the ORFs of other genomes and is also suitable for analyzing small genomes using software GeneDecipher, said method comprising steps of generating peptide libraries from the known genomes with peptide of length ‘N’ computationally arranged in an alphabetical order, artificially translating the test genome to obtain a polypeptide in each reading frame, converting each polypeptide sequence into an alphanumeric sequence with one corresponding to each reading frame on the basis of overlappings with the peptide libraries, training Artificial Neural Network (ANN) with sigmoidal learning function to the alphanumeric sequence, deciphering the protein coding regions in the test genome, thus, identifying longer streches of peptides mapping to large number of known genes and their corresponding proteins and lastly, a method of the management of the diseases caused by the pathogenic organisms comprising a step of evaluation of the proposed drug candidate by inhibiting the functioning of one or more proteins identified by the steps of the invention.

DETAILED DESCRIPTION OF THE PRESENT INVENTION

Accordingly, the present invention relates to a versatile method of identifying protein coding DNA sequences (genes) useful as drug targets in a genome using specially developed software GeneDecipher, said method comprising steps of generating peptide libraries from the known genomes with peptide of length ‘N’ computationally arranged in an alphabetical order, artificially translating the test genome to obtain a polypeptide corresponding to each reading frame, converting each polypeptide sequence into an alphanumeric sequence one corresponding to each reading frame on the basis of overlappings with the peptide libraries, training Artificial Neural Network (ANN) with sigmoidal learning function to the alphanumeric sequence, deciphering the protein coding regions in the test genome, thus, identifying longer streches of peptides mapping to large number of known genes and their corresponding proteins and lastly, a method of the management of the diseases caused by the pathogenic organisms comprising a step of evaluation of the proposed drug candidate by inhibiting the functioning of one or more proteins identified by the steps of the invention.

In an embodiment of the present invention, wherein a computer based versatile method for identifying protein coding DNA sequences useful as drug targets said method comprising steps of:

-   -   generating peptide libraries from the known genomes with         oligopeptide of length ‘N’ computationally arranged in an         alphabetical order,     -   artificially translating the test genome to obtain a polypeptide         in each reading frame,     -   converting each polypeptide sequence into an alphanumeric         sequence with one corresponding to each reading frame on the         basis of occurrence of these oligopeptides in the peptide         libraries,     -   training Artificial Neural Network (ANN) with sigmoidal learning         function to the alphanumeric sequences corresponding to known         protein coding DNA sequences and known non-coding regions,     -   deciphering the protein coding regions in the test genome, and     -   identifying longer stretches of peptides mapped to large number         of known genes serving as functional signatures.

In another embodiment of the present invention, wherein the artificial neural network has one or more input layer, one or more hidden layer with varying number of neurons, and one or more output layer.

In yet another embodiment of the present invention, wherein the number of neurons in the hidden layer is preferably 30.

In still another embodiment of the present invention, wherein the value of the ‘N’ is 4 or more.

In still another embodiment of the present invention, wherein the sigmoidal learning function has five parameters comprising total score, mean, fraction of zeroes, maximum continuous non-zero stretch, and variance.

In still another embodiment of the present invention, wherein the method of identifying genes using oligopeptides that are found to occur in the ORFs of other genomes but not limited to genomes such as H. influenzae, M. genitalium, E. coli, B. subtilis, A. fulgidis, M. tuberculosis, T. pallidum, T. maritima, Synecho cystis, H. pylori, and SARS-CoV.

In still another embodiment of the present invention, wherein a method claimed in claim 1, wherein the peptide library data may be taken from any organism but not specifically limited to those used in the invention.

In still another embodiment of the present invention, wherein a set of genes of SEQ ID Nos. 1 to 44 of H. influenzae, identified by using aforementioned method.

In still another embodiment of the present invention, wherein a set of proteins of SEQ ID Nos. 170 to 213 corresponding to genes of SEQ ID Nos 1 to 44 of H. influenzae, identified by using aforementioned method.

In still another embodiment of the present invention, wherein a set of genes of SEQ ID Nos. 45 to 60 of H. pylori, identified by using aforementioned method.

In still another embodiment of the present invention, wherein a set of proteins of SEQ ID Nos. 214 to 229 corresponding to genes of SEQ ID Nos 45 to 60 of H. pylori identified by using aforementioned method.

In still another embodiment of the present invention, wherein a set of genes of SEQ ID Nos. 61 to 165 of M. tuberculosis, identified by using aforementioned method.

In still another embodiment of the present invention, wherein a set of proteins of SEQ ID Nos. 230 to 334 corresponding to genes of SEQ ID Nos 61 to 165 of M. Tuberculosis, identified by using aforementioned method.

In still another embodiment of the present invention, wherein a set of genes of SEQ ID Nos. 166 to 169 of SARS-corona virus identified by using aforementioned method.

In still another embodiment of the present invention, wherein a set of proteins of SEQ ID Nos. 335 to 338 corresponding to genes of SEQ ID Nos 166 to 169 of SARS-corona virus, identified by using aforementioned method.

In still another embodiment of the present invention, wherein use of proteins of SEQ ID Nos. 170 to 338 corresponding to the genes of SEQ ID Nos. 1 to 169, as the drug target for the managing disease conditions caused by the pathogenic organisms in a subject in need thereof.

In still another embodiment of the present invention, wherein the pathogenic organisms are selected from a group comprising SARS-corona virus, H. influenzae, M. tuberculosis, and H. pylori.

In still another embodiment of the present invention, wherein the subject is an animal.

In still another embodiment of the present invention, wherein the subject is a human.

In still another embodiment of the present invention, wherein the use is extended to eukaryotes and multicellular organisms.

Emergence of high throughput sequencing technologies has necessitated identification of novel protein coding DNA sequences (genes) in newly sequenced genomes. The invention provides a novel method of converting DNA sequence to alphanumeric sequence by the use of peptide library. The invention also provides a method for use of artificial neural network (feed forward back propagation topology) with one input layer, one hidden layer with 30 neurons and one output layer for identification protein coding DNA sequences. The invention further provides a method for training of neural networks using sigmoid as a learning function with five parameters namely total score, mean, fraction of zeroes, maximum continuous non-zero stretch and variance for identification of protein coding DNA sequence.

The applicants have invented a novel computer based method to identify protein coding DNA sequences by comparing with peptide library containing millions of peptides obtained from protein sequences of many organisms that has withstood natural selection. The method describes a generic and versatile new approach for gene identification. The computational method determines gene candidates among all possible Open Reading Frames (ORF) of a given DNA sequence through the use of a peptide library and an artificial neural network. The peptide library consists of all possible overlapping heptapeptides derived from proteins of completely sequenced 56 or more prokaryotic genomes. A given query ORF qualifies as a gene based upon the abundance and distribution pattern of library heptapeptides (heptapeptides present in library) along the ORF. Performance of the method is characterized by simultaneous high values of sensitivity and specificity. An analysis of 10 completely sequenced prokaryotic genomes is provided to demonstrate the capabilities of the method of the invention.

The present method also allows prediction of alternate target against a specific peptide motif of a pathogenic organism or any host protein target responsible for a disease process. The method could be extended with different peptide lengths to obtain larger number of protein coding genes and also for eukaryotes and multicellular organisms.

The invention relates to a novel method of converting DNA sequence to alphanumeric sequence by the use of peptide library and the invention also provides a method for use of artificial neural network (feed forward back propagation topology) with one input layer, one hidden layer with 30 neurons and one output layer for identification protein coding DNA sequences. The invention further relates to a method for training of neural networks using sigmoid as a learning function with five parameters namely total score, mean, fraction of zeroes, maximum continuous non-zero stretch and variance for identification of protein coding DNA sequence and the present method is useful for identification of new protein coding regions which can serve as drug screen for broad-spectrum antibacterials as well as for specific diagnosis of infections, and in addition, for assignment of function to newly identified proteins of yet unknown functions. The method allows identification of species or strain specific protein coding genes. This method also can be extended to any protein coding sequence identification even in eukaryotic genomes.

Accordingly, present invention discloses a computer based versatile method for identifying protein coding DNA sequences useful as drug targets, said method comprising steps of:

-   -   a. generating peptide libraries from the known genomes with         oligopeptide of length ‘N’ computationally arranged in an         alphabetical order,     -   b. artificially translating the test genome to obtain a         polypeptide in each reading frame,     -   c. converting each polypeptide sequence into an alphanumeric         sequence with one corresponding to each reading frame on the         basis of occurrence of these oligopeptides in the peptide         libraries,     -   d. training Artificial Neural Network (ANN) with sigmoidal         learning function to the alphanumeric sequences corresponding to         known protein coding DNA sequences and known non-coding regions,     -   e. deciphering the protein coding regions in the test genome,         and     -   f. identifying longer stretches of peptides (evolutionary         conserved oligopeptides) mapped to large number of known genes         serving as functional signatures.

In yet another embodiment of the present invention the ANN has one or more input layer, one or more hidden layer with varying number of neurons, and one or more output layer.

In still another embodiment of the present invention the number of neurons in the hidden layer is preferably 30.

In yet another embodiment of the present invention the value of the ‘N’ is 4 or more.

In yet another embodiment of the present invention the sigmoidal learning function has five parameters comprising total score, mean, fraction of zeroes, maximum continuous non-zero stretch, and variance.

One more embodiment of the present invention a method of identifying genes having evolutionary conserved peptide sequences which occur in ORFs of various genomes but not limited to genomes such as H. influenzae, M. genitalium, E. coli, B. subtilis, A. fulgidis, M. tuberculosis, T. pallidum, T. maritima, Synecho cystis, H. pylori and SARS-CoV.

In still another embodiment of the present invention the method identifies 169 novel genes identified in genomes of SARS-corona virus and H. influenzae, M. tuberculosis, H. pylori of SEQ IDs 1 to 169.

In further embodiment of the present invention, a method of the management of the diseases caused by the pathogenic organisms such as SARS-corona virus, H. influenzae, M. tuberculosis and H. pylori, said method comprising step of evaluation of the proposed drug candidate for inhibition of the functioning of one or more evolutionary conserved peptide sequences identified by the instant method and selected from a group comprising proteins of SEQ IDs 170 to 338 corresponding to the novel genes of SEQ IDs 1 to 169.

In yet another embodiment of the present invention the peptide library data may be taken from any organism but not specifically limited to those used in the invention.

Detailed Methodology:

The method has been described in five major steps (as shown in FIG. 1):

-   -   1. Generation of a peptide library     -   2. Artificial translation of a given genome into 6 reading         frames     -   3. Conversion of each translated sequence into an alphanumeric         sequence. (one corresponding to each reading frame)     -   4. Training of artificial neural network (ANN).

5. Deciphering genes using trained ANN.

1. Generation of Peptide Library

The method requires a reference peptide library to predict genes in a given genome. In the present invention, the applicants have used proteins from 56 completely sequenced prokaryotic genomes. The protein files for our database were obtained in FASTA format from ftp://ftp.ncbi.nlm.nih.gov/genomes. To prepare a peptide library for deciphering genes in a particular genome, the applicants exclude protein file(s) belonging to that particular species from our database in order to avoid any bias. For example, when analyzing E. coli-k12 genome the protein files corresponding to all strains of E. coli were excluded from the database to create the peptide library. This has been done to eliminate the signal that is obtained from peptides of that organism, which would be the case while analyzing a newly sequenced genome. This strengthens the method in terms of gene prediction on a newly sequenced genome for which annotated protein file is not available. While creating peptide library all possible overlapping heptapeptides have been taken care of by shifting the window by one amino acid. Redundant peptides were eliminated from the peptide library and each peptide is given an occurrence value based on number of discrete organisms in which it is present.

This occurrence value is a measure of conservation of a heptapetide in coding regions. Presence of a heptapeptide with high occurrence value in an ORF increases the likelihood of that ORF being a protein coding gene. In our algorithm, occurrence value of 9 or more is treated as 9 based on the assumption that if a heptapeptide is present in 9 or more than 9 different organisms' protein files, it can be considered as highly conserved heptapeptide. It is not worthwhile to use any higher value to further discriminate the amount of conservation.

The heptapeptide library database consists of two columns, first for heptapeptide sequence and second for score (occurrence value) of that heptapeptide. Heptapeptides are sorted in dictionary order. The peptide library database also retains other information about the heptapeptides, like the accession number and NCBI annotation of all proteins containing the particular heptapeptide. This can be utilized for putative function prediction of a given ORF. Same approach can be used for phylogenetic domain analysis also.

2. Artificial Translation of a Given Genome into 6 Reading Frames

Second step in the algorithm is artificial translation of the whole query genome in all six reading frames using a standard codon table. However user specified codon table may be used wherever necessary. Applicants used letter ‘z’ corresponding to the stop codons TTA, TAG and TGA, and letter ‘b’ for all triplets containing any non standard nucleotide(s) (K, N, W, R, and S etc.) while artificially translating the genome.

3. Conversion of Each Translated Sequence into an Alphanumeric Sequence (One Corresponding to Each Reading Frame)

The next step in our algorithm is to convert artificially translated amino acid sequence with stop codon (z) interruption, into an alphanumeric sequence. Applicants search each overlapping heptapeptide in the peptide library, assign a corresponding number (occurrence value), and append it to the alphanumeric sequence. If a heptapeptide is not present in the library applicants assign the number 0. If a heptapeptide begins with an amino acid corresponding to any of the start codon ATG, GTG and TTG applicants append character ‘s’ in the alphanumeric sequence. This will be helpful to detect the location of a probable start codon. In case a heptapeptide contains character ‘z’ applicants append a character ‘*’ corresponding to that heptapeptide. Thus consecutive seven ‘*’ (*******) in the alphanumeric sequence is a signal for stop codon. Applicants append ‘-’ character for any heptapeptide containing character ‘b’. This signals the presence of a non standard nucleotide character and conveys no information about sequence being a part of gene or non-gene. So, the alphanumeric sequence thus generated contain 13 characters viz. any integer (0-9), ‘s’, ‘*’, and ‘-’. In this way, applicants convert all six translated protein files into six alphanumeric sequences.

4. Training of Artificial Neural Network (ANN)

The neural network used here has a multi-layer feed-forward topology. It consists of one input layer, one hidden layer, and an output layer. This is a ‘fully-connected’ neural network where each neuron i is connected to each unit j of the next layer (FIG. 2). The weight of each connection is denoted by w_(ij). The state I_(i) of each neuron in the input layer is assigned directly from the input data, whereas the states of hidden layer neurons are computed by using the sigmoid function, h_(j)=1/(1+exp−λ(w_(j0)+Σw_(ij)I_(i))), where, w_(j0) is the bias weight, and λ=1.

The back propagation algorithm is used to minimize the differences between the computed output and the desired output. One thousand cycles (epochs) of iterations are performed. Subsequently, the epoch with minimum error in validation set is identified and the corresponding weights (w_(ij)) are assigned as the final weights for the ANN. The network trains on the training set, checks error and optimizes using the validation set through back propagation.

The ‘training set’ consists of 1610 E. coli-k12 NCBI listed protein coding genes and 3000 E. coli-k12 ORFs (a stretch of sequence of length more than 20 amino acids and having start codon, stop codon in the same frame) which have not been reported as genes (non-genes). The ‘validation set’ has 1000 known genes and 1000 non-genes from E. coli-k12, distinct from those used in the training set. The ‘test set’ contains another 1000 genes and 1000 non-genes from the same organism. For training of the ANN, genes and the non-genes are assigned a probability value of 1 and 0 respectively.

To train the neural network, first applicants convert all the E. coli-k12 genes and non-genes into corresponding alphanumeric strings by the method described above (steps 2 and 3). Here it is important to note that the alphanumeric sequences corresponding to a gene is number rich compared to the alphanumeric sequences corresponding to non-genes. To quantify this number richness of an alphanumeric sequence, five parameters derived from the alphanumeric sequence have been selected. These five parameters are as follows:

(i). Total Score

This is an algebraic sum of all the integers of a given alphanumeric sequence. Here rule of thumb is higher the score, more are the chances to qualify as a gene.

(ii). Fraction of Zeroes

Fraction of zeroes equals to total no. of zero characters in the alphanumeric sequence divided by total no. of characters in the sequence. More the fraction of zeros, lesser is the chance to qualify as a gene.

(iii). Mean

Mean equals to total score divided by total length of the sequence. Higher the Mean, more is the chance to qualify as a gene. Virtually this parameter seems same as a total score but it is important because this incorporates the length of the sequence also (score per unit length)

(iv). Variance

It is the variance of occurrence values about the mean occurrence value for the whole ORF.

(v). Length of the Maximum Continuous Non Zero Stretch

Higher the value of this parameter more is the chance to qualify as a gene. Consider a sequence region like ‘45’. Here, ‘4’ denotes a heptapeptide conserved in 4 organisms, and the succeeding ‘5’ denotes an overlapping heptapeptide conserved in 5 organisms. So if there exists at least one organism which is common between these two sets, eventually applicants have an octapeptide common between that organism and the query ORF. This raises our confidence level in prediction of the coding region. For example, sequence ‘s45467000000*******’ is more likely to be a gene when compared to sequence ‘s40540607000*******’. This is because there are greater chances of presence of conserved longer peptide in the first sequence. Value of the parameter is 5 for first string and 2 for second one. However, other parameters used in the algorithm can not discriminate between these two sequences.

While calculating these parameters from the alphanumeric sequences, characters such as ‘s’, ‘*’ and ‘-’ have been excluded.

To find an optimum combination, the neural network is trained using all the five parameters together. Parameters corresponding to alphanumeric sequences of genes and non-genes are calculated. The training, validation and test sets contain 6 columns, first 5 columns contains values of the 5 parameters and the last column contains the number ‘1’ for genes and the number ‘0’ for non-genes.

The number of neurons in the input layer was equal to the number of input data points. The optimal number of neurons in the hidden layer was determined by hit and trial while minimizing the error at the best epoch for the network. Computer program to compute all 5 parameters and for the artificial neural network are written in C and executed on a PC under Red Hat Linux version 7.3 or 8.0.

Training of the ANN (step 4 of the algorithm) is generally executed only once, and the same trained neural network can be utilized to execute the method on any prokaryotic genome. Although if applicants use organism specific training set, results might improve in some cases, but it would be marginal. This is because our method predicts gene on the basis of the number distribution of the alphanumeric sequence of an ORF. So the gene prediction is more dependent on the peptide library used rather than training set.

5. Deciphering Genes Using Trained ANN

While creation of peptide library (step 1) and training of ANN (step 4) are considered as preparatory phases for executing the method of invention, step 2 and step 3 are mandatory for each genome sequence. After translating computationally a genome into all six reading frames and converting them into six alphanumeric sequences, deciphering genes using ANN is executed. This step can be further divided into following five sub-steps:

-   -   1. Breaking of all the six alphanumeric sequences into possible         ORFs. (all possible fragments starting with ‘s’ and ending with         ‘*’)     -   2. Calculate all the five parameters (total score, fraction of         zeroes, mean, variance, and length of maximum continuous non         zero stretch) for all possible ORFs (all the alphanumeric string         sequences between ‘s’ and ‘*’)     -   3. Calculate the probability of the ORF corresponding to a given         alphanumeric string as a protein coding gene, using the trained         ANN.

4. Filter out the protein coding ORFs from the non coding ones by using a cutoff probability value.

5. Remove all the encapsulated protein coding regions (Shibuya, T. and Rigoutsos, I., 2002).

-   -   If two ORFs are predicted in distinct translation frames, such         that one's span completely encapsulates other, it is a commonly         believed that only one of them can be an actual gene. In this         case the applicants report the ORF with a higher probability         value as a gene. In case of same probability value applicants         take longer ORF as a gene.

The method of the invention predicts a probability value corresponding to a query ORF being a protein coding region. The training of ANN is done using a sigmoid learning function with =1 (probability ‘1’for genes and ‘0’ for non-genes); therefore most of the time this probability value lies either below 0:1 or above 0.9. Due to this any cutoff value lying between 0.1 and 0.9 generate very similar results. In our analysis applicants use a default cutoff value of 0.5. It's important to note that the method does not require a trade-off between sensitivity and specificity because the choice of cut-off probability has no major consequences on the results.

Other and further aspects, features and advantages of the present invention will be apparent from the following description of the presently preferred embodiments of the invention given for the purpose of disclosures.

Brief Description of the Computer Programs:

1. File Name: genedcodchr.cxx

Application: Translation of nucleotide sequence (FASTA file format) into 6 hypothetical polypeptides in 6 respective frames. Input format : <Program_name> <Nucleotide_file> <Output1> <Output2> <frame> e.g., ./genedcodchr ecoli.fna pf1 pr1 0 Output format: AGTFYRYmGHVNMKIYTASLPTYRYGYFSHRED.....HGOIEKSDWEzDFGTRE 2. File Name: searchchr.cxx

Application: Converts the polypeptide file into an alphanumeric sequence through a heptapetide library (given as an input) search.  Input format :< Program_name> 7 <peptide library file name>  out Y <Input1> <Input2> <Output1> <Output 2>  e.g., ./searchchr 7 ecoli.peplib out Y pf1 pr1 bf1 br1  Output format:  s1124500001090003000020000023000000000*******0001000.......... 3. File Name: cutf.c

-   -   Application: Cuts all possible ORFs (i.e., all ‘s’ to ‘*’         regions) from the alphanumeric sequence of forward strand and         generates a file containing locations of all the ‘s’ in         alphanumeric sequence.     -   Input format:<Program_name><Input file         name><Output1><Output2>e.g./cutf bf1 unknown_bf1 bf1_location     -   Output format: output1—s1111000s00000000563*, output2—starting         locations of ‘s’ in a column.         4. File Name: cutr.c

Application: Cuts the all possible ORFs (all ‘s’ to ‘* regions) from the reverse strand's alphanumeric sequences and produces a file which contains the starting locations in alphanumeric sequence file for all 3 forward frames corresponding to all ORFs. Input format :< Program_name> <Input file name> <Output1> <Output2> e.g. ./cutr br1 unknown_br1 br1_location Outputformat: output1-*010340000222200067900000s000001000200s00230000s,

-   -   output2—starting location of ‘s’         5. File Name: stat.c

Application: Calculates the five parameters: fraction of zeros, mean, total score, length of maximum continuous stretch, and variance for a given alphanumeric sequence. Input format :< Program_name> <Input file name><Output> 1 e.g. ./stat unknown_bf1 bf1.data 1 Output format: 0.334 3.2 48 15 0.452 1 6. File Name: train .c

Application: Training of Artificial Neural Network (single hidden layer, 1 input and 1 output layer) with feed forward back propagation algorithm and using sigmoid (=1) as a learning function. Input format :< Program_name> <Input specification file name> <Input1> <Input2> <Input3> > output e.g. ./train train.spec.fast trainset.data validateset.data testset.data > train.net

-   -   Output format: output containing the final neural network         wieghts in a single column.         7. File Name: recognize.c

Application: Recognizes a given pattern on the basis of trained weights and generates a probability value as output. Input tormat :< Program_name> <Input specification file name> <Input1> <Input2> <Output> e.g. ./recognize recognize.spec bf1.data train.net f1.out Output format: pat1 probability <value> 8. File Name: Filter_prediction.c

Application: Filters out the completely overlapping ORFs in same frame based on probability and length parameter. Input format :< Program_name> <Input1> <Input2> <Output> e.g. ./Filter_prediction f1.out unknown_bf1 bf1.out.res Output format: pat1 probability <value> <integer string> 9. File Name: locationf.c

Application: Filters out the genes of length<20 amino acids, and reports starting location of the remaining ones with the alphanumeric sequence for all 3 forward frames. Input format :< Program_name> <Input1> <Output> <Input2> e.g. ./locationf bf1.out.res bf1.out.res1 bf1_location Output format:<Pattern No> <Probability value> <integer string> <Start> <End> 10. File Name: locationr.c

Application: Filters out the genes of length<20 amino acids, and reports starting location of the remaining ones with the alphanumeric sequence for all 3 reverse frames. Input format :< Program_name> <Input1> <Output> <Input2> e.g. ./locationr br1.out.res br1.out.res1 br1_location Output format:<Pattern No> <Probability value> <integer string> <Start> <End> 11. File Name: finalf.c

Application: Converts the start and end locations of the alphanumeric sequence into the corresponding genome locations for 3 forward frames. Input format :< Program_name> <Input1> <Input2> <Input3> <Output> e.g. ./finalf bf1.out.res1 bf2.out.res1 bf3.out.res1 Final_outputf Output format:<Start> <End> <frame> <length> <Probability value> <integer string> 12. File Name: finalr.c

Application: Converts the start and end locations of the alphanumeric sequence into the corresponding genome locations for 3 reverse frames. Input format :< Program_name> <Input1> <Input2> <Input3> <Output> e.g. ./finalf br1.out.res1 br2.out.res1 br3.out.res1 Final_outputr Output format:<Start> <End> <frame> <length> <Probability value> <integer string> 13. File Name: sort.c

-   -   File Name: sort.c

Applications: Prints the finally predicted genes into descending order along the genome start location. Input format :< Program_name> <Input1> <Input2> <Input3> <Output> e.g. ./sort Final_outputf Final_outputr OUTPUTF_with_encap OUTPUTR_with_encap OUTPUT Output format:<Start> <End> <Probability value> 14. File Name: removeencap.c

Application: Removes encapsulated genes found in other five frames. Input format :< Program_name> <Input1> <Input2> <Input3> <Output> e.g. ./removeencap OUTPUTF_with_encap OUTPUTR_with_encap OUTPUT OUTPUTF OUTPUTR Output format:<Start> <End> <frame> <length> <Probability value> <integer string>

The present invention relates to a novel computer based method for predicting protein coding DNA sequences useful as drug targets. In this method occurrence of oligopeptide signatures have been used as probes. The method is versatile and does not necessarily require organism specific training set for the Artificial Neural Network. The method is not only dependent on statistical analysis but also integrates with the biological information that is retained in the conserved peptides, which withstood evolutionary pressure. Logical extension of the method will be to predict protein coding DNA sequences (exons) in eukaryotic genomes.

BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS

FIG. 1 shows a logic circuit of GeneDecipher.

FIG. 2 shows a architecture of neural network.

FIG. 3 shows analysis of results of GeneDecipher on 10 organisms.

The particulars of the organisms used for the invention comprising name, strain, accession number and other details are given below. Date of S. No. Genome Strain Accession Number Total Base Sequences Completion 1 H. Influenzae Rd NC_000907 1830138 Sep. 30, 1996 Fleischmann, R. D. et. al Science 269 (5223), 496-512 (1995) 2 M. Genitalium — NC_000908 580074 Jan. 8, 2001 Fraser, C. M., et. al Science 270 (5235), 397-403 (1995 3 E. coli K-12 NC_000913 4639221 Oct. 15, 2001. Blattner, F. R. et. al Science 277 (5331), 1453-1474 (1997) 4 B. Subtilis  168 NC_000964 4214814 Nov. 20, 1997 Kunst, F. et. al Nature 390 (6657), 249-256 (1997) 5 A. Fulgidis DSM 4304 NC_000917 2178400 Dec. 17, 1997 Klenk, H. P. et. al Nature 390 (6658), 364-370 (1997) 6 M. Tuberculosis H37RV NC_000962 4411529 Sep. 7, 2001 Cole, S. T. et. al Nature 393 (6685), 537-544 (1998) 7 T. Pallidum — NC_000919 1138011 Sep. 7, 2001 Fraser, C. M., et. al Science 281 (5375), 375-388 (1998) 8 T. Maritima — NC_000853 1860725 Sep. 10, 2001. Nelson, K. E. et. al Nature 399 (6734), 323-329 (1999) 9 Synecho cystis PCC6803 NC_000911 3573470 Oct. 30, 1996 Kaneko, T. et. al DNA Res. 3(3), 109-136 (1996) 10 H. Pylori 26695 NC_000915 1667867 Sep. 7, 2001 Tomb, J. -F. et. al Nature 388 (6642), 539-547 (1997)

The following examples are given by way of illustration of the present invention and should not be construed to limit the scope of the present invention.

EXAMPLE 1

Conversion of DNA Sequence into Alphanumeric Sequence

The purpose of this module in our software is to translate computationally the whole query genome (DNA sequence) in all six reading frames using a specified codon table. Applicants used letter ‘z’ corresponding to the stop codons TTA, TAG and TGA, and letter ‘b’ for all triplets containing any non standard nucleotide(s) (K, N, W, R, and S etc.) while artificially translating the genome. Subsequently the translated genome sequence is converted computationally into an alphanumeric sequence ([0-9], ‘s’, ‘*’, and ‘-’). Applicants search each overlapping heptapeptide in the peptide library, assign a corresponding number (occurrence value), and append it to the alphanumeric sequence. If a heptapeptide is not present in the library applicants assign the number 0. If a heptapeptide begins with an amino acid corresponding to any of the start codon ATG, GTG and TTG Applicants append character ‘s’ in the alphanumeric sequence. This will be helpful to detect the location of a probable start codon. In case a heptapeptide contains character ‘z’ applicants append a character ‘*’ corresponding to that heptapeptide. Thus consecutive seven ‘*’ (*******) in the alphanumeric sequence is a signal for stop codon. Applicants append a ‘-’ character for any heptapeptide containing character ‘b’. This signals the presence of a non-standard nucleotide character.

The aforementioned conversion is further elaborated with the help of following six sequences. SEQ ID No. 12 GDC_HINF_243018 243018 243215 65 + Cell wall-associated hydrolase >gi_GDC_HINF_243018 GTGATGAGCCGACATCGAGGTGCCAAACACCGCCGTCGATATGAACTCTTGGG CGGTATCAGCCTGTTATCCCCGGAGTACCTTTTATCCGTTGAGCGATGGCCCTT CCATTCAGAACCACCGGATCACTATGACCTACTTTCGTACCTGCTCGACTTGTC TGTCTCGCAGTTAAGCTTGCTTATACCATTGCACTAA

Computationally Translated Protein Sequence >gi_GDC_HINF_243018 VMSRHRGAKHRRRYELLGGISLLSPEYLLSVERWPFHSEPPDHYDLLSYLLDLSVSQLSLLIPLH Computationally Generated Alphanumeric Sequence

ss10000000000001s03111431000000000000000000110000100s001030* SEQ ID No. 4 GDC_HINF_170553 170553 170732 59 − dicarboxylate transport protein homolog HI0153 >gi_GDC_HINF_170553 GTGTTTATGCTTTATTTAGAATTTTTATTTTTACTATTAATGCTCTATATCGGTA GCCGTTACGGCGGTATCGGATTAGGTGTTGTTTCTGGTATCGGTCTTGCTATCG AGGTTTTCGTATTTCGTATGCCAGTGGGGAAGCACCGATTGATGTTATGCTTAT CATTCTTGCAGTGGTGA

Computationally Translated Protein Sequence >gi_GDC_HINF_170553 VFMLYLEFLFLLLMLYIGSRYGGIGLGVVSGIGLAIEVFVFRMPVGKHRLMLCLSFLQW Computationally Generated Alphanumeric Sequence

s0s1131231142s1111445232254238000000000000s0s0000ss00* SEQ ID No. 73 GDC_MTUB_688806 688806 689060 84 + MCE-FAMILY PROTEIN MCE2B >gi_GDC_MTUB_688806 TTGCTGCACAGCAGCTTCGGGCACCTCGAGGGCATCCAGCAGCCGCTCATAGA CGAGCTGGCAGAACTCGACCACGTGTTGGGCAAGCTGCCGGACGCCTACCGGA TCATCGGCCGCGCCGGCGGCATATACGGTGACTTCTTCAACTTCTATCTGTGTG ACATCTCACTGAAAGTCAACGGATTACAGCCTGGAGGTCCGGTACGCACCGTC AAGTTGTTCGGCCAGCCGACCGGCAGGTGCACACCGCAATGA

Computationally Translated Protein Sequence >gi_GDC_MTUB_688806 LLHSSFGHLEGIQQPLIDELAELDHVLGKLPDAYRIIGRAGGIYGDFFNFYLCDISLK VNGLQPGGPVRTVKLFGQPTGRCTPQ Computationally Generated Alphanumeric Sequence

s000000000110110530100000ss000000000000100000000000000000001111210000000s00100* SEQ ID No. 92 GDC_MTUB_1286282 1286282 1286587 101 − pterin-4-alpha- carbinolamine dehydratase >gi_GDC_MTUB_1286282 GTGACGGTATACCGTCGAGGTATGGCTGTGTTAACGGATGAGCAGGTCGACGC CGCACTGCACGACCTCAACGGCTGGCAGCGCGCCGGTGGTGTCCTGCGTAGGT CAATCAAGTTTCCGACGTTTATGGCCGGTATCGACGCCGTACGCCGGGTGGCC GAGCGAGCCGAGGAGGTAAATCATCATCCGGACATCGATATCCGTTGGCGAAC AGTAACTTTCGCGCTGGTTACGCATGCGGTAGGTGGTATCACGGAAAACGACA TTGCGATGGCGCACGATATCGACGCAATGTTTGGGGCCTAA

Computationally Translated Protein Sequence >gi_GDC_MTUB_1286282 VTVYRRGMAVLTDEQVDAALHDLNGWQRAGGVLRRSIKFPTFMAGIDAVRRVA ERAEEVNHHPDIDIRWRTVTFALVTHAVGGITENDIAMAHDIDAMFGA Computationally Generated Alphanumeric Sequence

s000000s0s21110001000000300000000011000000s01031100s00020000110000000030000000013310000000s0001* SEQ ID No. 49 GDC_HPYL_583607 583607 583876 89 + probable DNA helicase >gi_GDC_HPYL_583607 TTGATGGAATTTGATGTTACCATCATAGATGAGACAGGCAGGGCCACAGCACC AGAAATCTTGATTCCTGCACTTCGCACTAAAAAACTGATCTTAATAGGCGATC ACAACCAGCTCCCACCTAGCATTGATAGGTACCTCCTAGAACAATTAGAGAGC GATGATATTCAAAACTTGGATGCCATTGATCGCCAATTATTGGAAGAGAGTTT TTTTGAAAATCTCTATAAGTATATTCCAGAGAGTAATAAGGCCATGCTTAATG AGTAA

Computationally Translated Protein Sequence >gi_GDC_HPYL_583607 LMEFDVTIIDETGRATAPEILIPALRTKKLILIGDHNQLPPSIDRYLLEQLESDDIQNL DAIDRQLLEESFFENLYKYIPESNKAMLNE Computationally Generated Alphanumeric Sequence

ss001000000001000000s0000011000020000000000030310000000002s0003020s0000000000000000* SEQ ID No. 54 GDC_HPYL_954846 954846 955217 123 − PHOSPHOTRANSACETY LASE >gi_GDC_HPYL_954846 GTGAGCCTGGTTTCAAGCGTGTTTTTAATGTGTTTAGACACTCAAGTGCTAGTC TTTGGGGATTGCGCGATTATCCCTAACCCTAGCCCTAAAGAATTAGCCGAGAT CGCTACCACTTCCGCACAAACCGCCAAGCAATTCAATATTGCGCCTAAAGTGG CCTTGCTTTCTTATGCGACAGGCGATTCCGCTCAAGGCGAAATGATAGACAAA ATCAACGAAGCTTTAACAATCGCTCAAAAGTTGGATCCCCAATTAGAAATTGA TGGCCCCTTACAATTTGACGCTTCCATTGATAAAAGCGTAGCCAAGAAAAAAT GCCTAACAGCCAAGTGGCTGGGCAAGCTAGCGTTTTTATTTTCCCGGATTTAA

Computationally Translated Protein Sequence >gi_GDC_HPYL_954846 VSLVSSVFLMCLDTQVLVFGDCAIIPNPSPKELAEIATTSAQTAKQFNIAPKVALLS YATGDSAQGEMIDKINEALTIAQKLDPQLEIDGPLQFDASIDKSVAKKKCLTAKWL GKLAFLFSRI Computationally Generated Alphanumeric Sequence

-   s80000s00s00002s200222000000003100000000000000000010s0s100000000000s0000000100000s00000000000000000000000000030000010*

EXAMPLE 2

Training of Artificial Neural Network (ANN)

The purpose of this module in the software is to train the designed neural network (FIG. 2) with a specified no. of genes and non-genes. In this example the training set consists of 1610 E. coli-k12 NCBI listed protein coding genes and 3000 E. coli-k12 ORFs which have not been reported as genes (non-genes). The validation set has 1000 known genes and 1000 non-genes from E. coli-k12, distinct from those used in the training set. The test set contains another 1000 genes and 1000 non-genes from the same organism. For training of the ANN, genes and the non-genes are assigned a probability value of 1 and 0 respectively. To train the neural network, first applicants convert all the E. coli-k12 genes and non-genes into corresponding alphanumeric strings by the method described above (steps 2 and 3). Samples of two E. coli-k12 genes and two non-genes in alphanumeric sequence format are shown in FIG. 3. Here it is important to note that the alphanumeric sequences corresponding to a gene is number rich compared to the alphanumeric sequences corresponding to non-genes. This supports our hypothesis. To quantify this number richness of an alphanumeric sequence, five parameters derived from the alphanumeric sequence have been selected. These five parameters are as follows:

Total Score (algebraic sum of all the integers of a given alphanumeric sequence), Fraction of zeroes (total no. of zero characters in the alphanumeric sequence divided by total no. of characters in the sequence), Mean (total score divided by total length of the sequence), Variance (variance of occurrence values about the mean occurrence value for the whole ORF), Length of the maximum continuous non zero stretch (represents the occupancy of uninterrupted non-zero numbers in a sequence) as explained in table 1(a) and 1(b). TABLE 1(a) Training of ANN (genes) Biggest S. Fraction Total Continuous No of Zeros Score Average stretch Variance Probability 1 0.663116 587 0.7816 19 2.10146 1 2 0.693950 214 0.7616 18 2.43068 1 3 0.597436 412 1.0590 13 3.16832 1 4 0.898876 12 0.1348 4 0.20654 1

TABLE 1(b) Training of ANN (Non-genes) Biggest S. Fraction Total Continuous No of Zeros Score Average stretch Variance Probability 1 0.946429 3 0.0536 2 0.05070 0 2 1.000000 0 0.0000 0 0.00000 0 3 0.955556 2 0.0444 1 0.04247 0 4 0.956522 2 0.0435 1 0.04159 0

While calculating these parameters from the alphanumeric sequences characters ‘s’, ‘*’ and ‘-’ have been excluded. To determine the contribution of each parameter towards discriminating genes from non-genes, the neural network is trained using all the five parameters together. Parameters corresponding to alphanumeric sequences of genes and non-genes are calculated. The training, validation and test sets contain 6 columns, first 5 columns contains values of the 5 parameters and the last column contains the number ‘I’ for genes and the number ‘0’ for non-genes.

EXAMPLE 3

The applicants have analyzed 10 prokaryotic genomes using the method of invention. Efficiency of the method has been defined as percentage of the NCBI listed protein coding regions predicted by said method. All the encapsulated protein coding regions have been eliminated automatically by a specifically developed program. The method is able to predict on an average 92.7% of the NCBI listed genes with a standard deviation of 2.8%. Both sensitivity and specificity values of the method are high except in M. tuberculosis H37RV genome (as shown in FIG. No. 3).

EXAMPLE 4

Prediction of Start Site of Protein Coding DNA Sequences

Correct start site prediction rate of the method of invention varies from 49.5% in M. tuberculosis H37Rv (where specificity is also least) to 81.1% in H. pylori 26695. The applicants method decides start location based on the presence of start codon plus conservation of the surrounding heptapeptides. This method can also be utilized to predict the start site of a query protein coding DNA sequences predicted by some other method. This can be done by simply converting the protein sequence into corresponding integer sequence and then deciding the valid start site ‘s’ on the basis of surrounding heptapeptides. The applicants report three such cases from E. coli K-12 genome (two from the forward strand and one from the reverse strand), to exemplify the start site prediction (as shown below).

In prediction of start site there is a trade-off between number richness and length of the ORF. In Case 1 (PID 16132273), the start location of the gene has been shifted from location 85540 to 85630 by NCBI. By visual inspection of the integer sequences corresponding to this gene it is evident that earlier there was a region after ‘s’ which was full of zeroes; or in other terms not a number rich region (bold region in Case 1 of figure shown below). The start site has now been shifted so that it now lies before a number rich region as predicted by the said method of invention. Case 2 is an example of 5′ upstream shifting of the start codon because there is a number rich region (‘2011111’ and one ‘3’ and one ‘2’) upstream of this start codon. So this has been shifted to location 4611050 from 4611194. Case 3 is another example of shifting of start site in the reverse strand where there is a number rich region (‘16531311’ and many other numbers in the string) upstream of the earlier NCBI start location.

s0s0000000000000s000000000s000s2ss4222s111000000000999922224210000s00s40004 466442223s0s0120000000177s9999855553239888440s001111000113002s1116311112ss 22222s430100000000100s0100000639977100011100100000001000000000s2000010030 000011110111100000161171000000000s201s12s0000002ss10000000001099s76s621110 0s0s0000s00014444441111100000000000234331211000s033221s000000014s000s00000 002000000000001110000000000000000000s000001s000000s48976531s11111100012234 59999999s92554010010s0s0002s2236667778s75221001s000s000ss00000066ss11111s32 11100000s000002204332110000000000210010010000s00000s11000000354211s000000s 00s22*******

s00020111110000000000000300000000020000010000030ss000000001110s0s000ss0000 0s102110000000100ss3s2000000000000000000000100021100011s110000000000s00000 000001s10100000010100002222222000000000000000010321002s3321111s1101111001 0000000s00s000s00101010100s00000*******

EXAMPLE 5

Prediction of Protein Coding DNA Sequences

The method is utilized for prediction of protein coding DNA sequences for various genomes in a publicly available database (NCBI) by employing the following steps:

-   i) generating computationally overlapping peptide libraries from all     the protein sequences of the selected organisms available at     http://www.ncbi.nlm.nih.gov, -   ii) sorting computationally the peptides of length ‘N’ obtained as     above, alphabetically, according to single letter amino acid code, -   iii) cataloging every peptide and their unique occurrence different     organisms, -   iv) converting DNA sequence to alphanumeric sequence using peptide     library obtained from steps 1 and 2, -   v) retrieving all possible open reading frames (ORFs) from the     alphanumeric sequence, -   vi) training of the modified neural network for discriminating     protein coding and non-coding DNA sequences, -   vii) predicting DNA coding sequences in the open reading frames     (obtained in step 4) using trained neural network, -   viii) removing the encapsulated protein coding DNA sequences (genes     within genes)

Using the steps of the invention the inventors have arrived at disclosure of novel 169 genes from the genomes of organisms selected from SARS-corona virus, H. influenzae, M. tuberculosis, and H. pylori as detailed in the table 2. The Table No. 2 provides the said novel genes in the sequence of SEQ ID No. 1 to SEQ ID No. 169. TABLE 2 1 GDC_HINF_(—) 5641 6273 210 + Formate dehydrogenase major 5641 subunit 2 GDC_HINF_(—) 6322 8748 808 + Formate dehydrogenase major 6322 subunit 3 GDC_HINF_(—) 124181 124378 65 + Cell wall-associated hydrolase 124181 4 GDC_HINF_(—) 170553 170732 59 − dicarboxylate transport protein 170553 homolog HI0153 5 GDC_HINF_(—) 231874 232173 99 + type I restriction system 231874 adenine methylase 6 GDC_HINF_(—) 232170 232991 273 + type I restriction system 232170 adenine methylase 7 GDC_HINF_(—) 232813 233139 108 + type I restriction system 232813 adenine methylase 8 GDC_HINF_(—) 233190 233393 67 + Type I restriction enzyme 233190 EcoprrI M protein 9 GDC_HINF_(—) 235441 235932 163 + prrD protein homolog 235441 10 GDC_HINF_(—) 235913 238519 868 + Type I restriction enzyme 235913 EcoR124II R protein 11 GDC_HINF_(—) 240336 241379 347 − Aerobic respiration control 240336 sensor protein 12 GDC_HINF_(—) 243018 243215 65 + Cell wall-associated hydrolase 243018 13 GDC_HINF_(—) 274892 276853 653 − Adhesion and penetration 274892 protein precursor 14 GDC_HINF_(—) 276992 279121 709 − Adhesion and penetration 276992 protein precursor 15 GDC_HINF_(—) 370413 370808 131 + NapA 370413 16 GDC_HINF_(—) 370747 372912 721 + NapA 370747 17 GDC_HINF_(—) 628407 628604 65 − Cell wall-associated hydrolase 628407 18 GDC_HINF_(—) 654365 655015 216 − Probable D-methionine 654365 transport system permease 19 GDC_HINF_(—) 661444 661641 65 − Cell wall-associated hydrolase 661444 20 GDC_HINF_(—) 737160 737297 45 + glycerophosphodiester 737160 phosphodiesterase 21 GDC_HINF_(—) 775792 775989 65 − Cell wall-associated hydrolase 775792 22 GDC_HINF_(—) 848166 848678 170 − ribosomal protein 848166 23 GDC_HINF_(—) 928073 929080 335 + Peptidase B (Aminopeptidase 928073 B) 24 GDC_HINF_(—) 929037 929402 121 + Peptidase B (Aminopeptidase 929037 B) 25 GDC_HINF_(—) 1018846 1021371 841 − Isoleucyl-tRNA synthetase 1018846 26 GDC_HINF_(—) 1021582 1021683 33 − Isoleucyl-tRNA synthetase 1021582 27 GDC_HINF_(—) 1082407 1082514 35 − protein V6, truncated - 1082407 Haemophilus influenzae 28 GDC_HINF_(—) 1144501 1145004 167 − PnuC transporter 1144501 29 GDC_HINF_(—) 1279189 1279935 248 − Peptide chain release factor 2 1279189 (RF-2) 30 GDC_HINF_(—) 1347200 1347445 81 + putative ABC transport protein 1347200 31 GDC_HINF_(—) 1347942 1348478 178 + putative iron compound ABC 1347942 transporter 32 GDC_HINF_(—) 1476415 1476615 66 − PstB 1476415 33 GDC_HINF_(—) 1476557 1477183 208 − PstB 1476557 34 GDC_HINF_(—) 1505851 1506048 65 − terminase large subunit 1505851 35 GDC_HINF_(—) 1524561 1525421 286 − ThiI 1524561 36 GDC_HINF_(—) 1568974 1569300 108 + DNA-binding protein rdgB 1568974 homolog 37 GDC_HINF_(—) 1586944 1587765 273 + putative tail protein 1586944 38 GDC_HINF_(—) 1594339 1594854 171 − NifC 1594339 39 GDC_HINF_(—) 1634710 1636722 670 + Probable hemoglobin and 1634710 hemoglobin-haptoglobin 40 GDC_HINF_(—) 1638626 1639372 248 − Putative integrase/recombinase 1638626 HI1572 41 GDC_HINF_(—) 1639409 1639726 105 − Putative integrase/recombinase 1639409 HI1572 42 GDC_HINF_(—) 1660491 1662080 529 − Cell division protein ftsK 1660491 homolog 43 GDC_HINF_(—) 1807963 1808859 298 − adhesin homolog HI1732 1807963 44 GDC_HINF_(—) 1817220 1817417 65 + Cell wall-associated hydrolase 1817220 45 GDC_HPYL_(—) 51094 51432 112 − putative HP0052-like protein 51094 46 GDC_HPYL_(—) 155367 156164 265 − 2-oxoglutarate/malate 155367 translocator 47 GDC_HPYL_(—) 447632 447850 72 − Cell wall-associated hydrolase 447632 48 GDC_HPYL_(—) 506250 507134 294 + site-specific DNA- 506250 methyltransferase 49 GDC_HPYL_(—) 583607 583876 89 + probable DNA helicase 583607 50 GDC_HPYL_(—) 583883 584437 184 + probable DNA helicase 583883 51 GDC_HPYL_(—) 665045 665695 216 + putative lipopolysaccharide 665045 biosynthesis protein 52 GDC_HPYL_(—) 953783 954664 293 − acetate kinase 953783 53 GDC_HPYL_(—) 954679 954900 73 − phosphate acetyltransferase 954679 54 GDC_HPYL_(—) 954846 955217 123 − PHOSPHOTRANSACETYLASE 954846 55 GDC_HPYL_(—) 955261 955557 98 − phosphate acetyltransferase 955261 56 GDC_HPYL_(—) 1068602 1069459 285 − IS606 TRANSPOSASE 1068602 57 GDC_HPYL_(—) 1069456 1069929 157 − transposase-like protein, 1069456 PS3IS 58 GDC_HPYL_(—) 1376803 1377126 107 + ribosomal protein 1376803 59 GDC_HPYL_(—) 1474291 1474509 72 + Cell wall-associated hydrolase 1474291 60 GDC_HPYL_(—) 1600102 1600689 195 − TYPE III DNA 1600102 MODIFICATION ENZYME 61 GDC_MTUB_(—) 26830 27534 234 − putative protoporphyrinogen 26830 oxidase 62 GDC_MTUB_(—) 36276 36785 169 − fibronectin-attachment protein 36276 FAP-P 63 GDC_MTUB_(—) 76032 76595 187 + retinoblastoma inhibiting gene 76032 1 64 GDC_MTUB_(—) 80423 81214 263 − mucin 5 80423 65 GDC_MTUB_(—) 167239 168084 281 + putative secreted peptidase 167239 66 GDC_MTUB_(—) 214625 215116 163 − glycoprotein gp2 214625 67 GDC_MTUB_(—) 424142 424657 171 − PPE FAMILY PROTEIN 424142 68 GDC_MTUB_(—) 459316 461076 586 + 63 kDa protein 459316 69 GDC_MTUB_(—) 549643 550758 371 − carR 549643 70 GDC_MTUB_(—) 566823 567284 153 + MAPK-interacting and 566823 spindle-stabilizing protein 71 GDC_MTUB_(—) 591109 591345 78 + excisionase, putative 591109 72 GDC_MTUB_(—) 663028 663426 132 + PROBABLE 663028 RIBONUCLEOSIDE- DIPHOSPHATE REDUCTASE 73 GDC_MTUB_(—) 688806 689060 84 + MCE-FAMILY PROTEIN 688806 MCE2B 74 GDC_MTUB_(—) 701762 702643 293 − u1764ad 701762 75 GDC_MTUB_(—) 731710 731877 55 + ribosomal protein L33 731710 76 GDC_MTUB_(—) 772761 773402 213 − ENSANGP00000004917 772761 77 GDC_MTUB_(—) 868821 869216 131 − cold-shock induced protein of 868821 the Srp1p/Tip1p 78 GDC_MTUB_(—) 890358 891254 298 − orf2 890358 79 GDC_MTUB_(—) 904043 904840 265 + aminoimidazole ribotide 904043 synthetase 80 GDC_MTUB_(—) 1045383 1046129 248 + u650i 1045383 81 GDC_MTUB_(—) 1068100 1068726 208 − anchorage subunit of a- 1068100 agglutinin; Aga1p 82 GDC_MTUB_(—) 1115707 1116369 220 − mucin 7 precursor, salivary 1115707 83 GDC_MTUB_(—) 1124996 1125712 238 − putative oxidoreductase 1124996 84 GDC_MTUB_(—) 1138949 1139665 238 − platelet binding protein GspB 1138949 85 GDC_MTUB_(—) 1170285 1170749 154 − MC8 1170285 86 GDC_MTUB_(—) 1176592 1176858 88 + gp85 1176592 87 GDC_MTUB_(—) 1202653 1203198 181 − s19 chorion protein 1202653 88 GDC_MTUB_(—) 1231843 1232460 205 + carboxylesterase 1231843 89 GDC_MTUB_(—) 1241031 1241468 145 − PE 1241031 90 GDC_MTUB_(—) 1252888 1253748 286 − ppg3 1252888 91 GDC_MTUB_(—) 1264312 1264554 80 + ketoacyl-CoA thiolase-related 1264312 protein 92 GDC_MTUB_(—) 1286282 1286587 101 − pterin-4-alpha-carbinolamine 1286282 dehydratase 93 GDC_MTUB_(—) 1301742 1302053 103 − similar to ORF starts at 87, 1301742 first start codon 94 GDC_MTUB_(—) 1351907 1352614 235 − ppg3 1351907 95 GDC_MTUB_(—) 1476279 1476647 122 − Cell wall-associated hydrolase 1476279 96 GDC_MTUB_(—) 1485311 1486399 362 − 4-hydroxyphenylpyruvate 1485311 dioxygenase C terminal 97 GDC_MTUB_(—) 1486309 1487727 472 − cell wall surface anchor family 1486309 protein 98 GDC_MTUB_(—) 1515112 1515846 244 − putative ABC transporter ATP 1515112 binding protein 99 GDC_MTUB_(—) 1515464 1516198 244 − extracellular protein, gamma- 1515464 D-glutamate-meso-d . . . 100 GDC_MTUB_(—) 1596569 1596892 107 − putative translation initiation 1596569 factor IF-2 101 GDC_MTUB_(—) 1600905 1601861 318 − carboxylesterase family 1600905 protein 102 GDC_MTUB_(—) 1616064 1616951 295 − PUTATIVE 1616064 TRANSCRIPTION REGULATOR PROTEIN 103 GDC_MTUB_(—) 1672449 1673216 255 + MAV278 1672449 104 GDC_MTUB_(—) 1673708 1675000 430 − MAV301 1673708 105 GDC_MTUB_(—) 1699549 1700226 225 + gmdA 1699549 106 GDC_MTUB_(—) 1742061 1742858 265 − ENSANGP00000020758 1742061 107 GDC_MTUB_(—) 1782153 1782932 259 + GLP_26_54603_52153 1782153 108 GDC_MTUB_(—) 2060659 2061114 151 + nuclear factor of kappa light 2060659 polypeptide gene 109 GDC_MTUB_(—) 2093062 2093994 310 − PROBABLE 6- 2093062 PHOSPHOGLUCONATE DEHYDROGENASE GND1 110 GDC_MTUB_(—) 2105797 2106912 371 + ATP-binding subunit of ABC- 2105797 transport system 111 GDC_MTUB_(—) 2133554 2134069 171 − KIAA0324 protein 2133554 112 GDC_MTUB_(—) 2183418 2184026 202 − putative transport protein 2183418 113 GDC_MTUB_(—) 2192571 2193488 305 − putative oxidoreductase 2192571 114 GDC_MTUB_(—) 2234641 2234889 82 − DNA-binding protein, CopG 2234641 family 115 GDC_MTUB_(—) 2320829 2321062 77 + DNA-binding protein, CopG 2320829 family 116 GDC_MTUB_(—) 2321250 2322509 419 − cell wall surface anchor family 2321250 protein 117 GDC_MTUB_(—) 2487508 2488524 338 − ORF1 2487508 118 GDC_MTUB_(—) 2567990 2568457 155 + B1158F07.3 2567990 119 GDC_MTUB_(—) 2577106 2577699 197 + POSSIBLE CONSERVED 2577106 MEMBRANE PROTEIN 120 GDC_MTUB_(—) 2577486 2577920 144 + POSSIBLE CONSERVED 2577486 MEMBRANE PROTEIN 121 GDC_MTUB_(—) 2690012 2690509 165 + PROBABLE CONSERVED 2690012 INTEGRAL MEMBRANE PROTEIN 122 GDC_MTUB_(—) 2698040 2698243 67 − POSSIBLE CONSERVED 2698040 MEMBRANE PROTEIN 123 GDC_MTUB_(—) 2712275 2714008 577 + MLCL536.10 protein 2712275 124 GDC_MTUB_(—) 2725593 2725859 88 − PROBABLE HYDROGEN 2725593 PEROXIDE-INDUCIBLE GENES 125 GDC_MTUB_(—) 2733212 2734420 402 − lycoprotein gp2 2733212 126 GDC_MTUB_(—) 2828257 2828937 226 + MC8 2828257 127 GDC_MTUB_(—) 2895354 2897222 622 + antigen T5 2895354 128 GDC_MTUB_(—) 2983047 2984033 328 − MC8 2983047 129 GDC_MTUB_(—) 3005316 3005696 126 − ABC transporter, ATP-binding 3005316 protein 130 GDC_MTUB_(—) 3048559 3049095 178 − recX protein 3048559 131 GDC_MTUB_(—) 3065095 3066549 484 + ppg3 3065095 132 GDC_MTUB_(—) 3100192 3100452 86 − IS1537, transposase 3100192 133 GDC_MTUB_(—) 3129118 3129594 158 − KIAA1139 protein 3129118 134 GDC_MTUB_(—) 3237815 3238096 93 − acylphosphatase 3237815 135 GDC_MTUB_(—) 3283182 3283718 178 − Putative mycocerosyl 3283182 transferase in MAS 5′r . . . 136 GDC_MTUB_(—) 3289702 3290232 176 + POSSIBLE TRANSPOSASE 3289702 137 GDC_MTUB_(—) 3319076 3319546 156 − u0002d 3319076 138 GDC_MTUB_(—) 3339006 3339851 281 − membrane glycoprotein 3339006 139 GDC_MTUB_(—) 3356995 3357831 278 − sensor histidine kinase 3356995 140 GDC_MTUB_(—) 3381198 3381755 185 + MC8 3381198 141 GDC_MTUB_(—) 3388071 3389003 310 + cellulosomal scaffoldin 3388071 anchoring protein C 142 GDC_MTUB_(—) 3482312 3482770 152 − MC8 3482312 143 GDC_MTUB_(—) 3581973 3582620 215 + similar to mucin, submaxillary - 3581973 pig 144 GDC_MTUB_(—) 3711717 3712613 298 − orf2 3711717 145 GDC_MTUB_(—) 3716987 3718534 515 − similar to profilaggrin - human 3716987 (fragments) 146 GDC_MTUB_(—) 3754581 3755711 376 − putative transposase 3754581 147 GDC_MTUB_(—) 3794808 3795026 72 − deoxyxylulose-5-phosphate 3794808 synthase 148 GDC_MTUB_(—) 3796793 3797512 239 + membrane glycoprotein 3796793 [imported] - equine herpesvirus 149 GDC_MTUB_(—) 3879013 3879534 173 − ribosomal protein S11 3879013 150 GDC_MTUB_(—) 3921024 3921665 213 − 3-oxoacyl-(acyl-carrier- 3921024 protein) reductase 151 GDC_MTUB_(—) 3974481 3975056 191 + mucin 10 3974481 152 GDC_MTUB_(—) 3994808 3995446 212 + MAV278 3994808 153 GDC_MTUB_(—) 3998938 3999642 234 − protease inhibitor/seed 3998938 storage/lipid transfer 154 GDC_MTUB_(—) 4021183 4021425 80 − PUTATIVE TRNA/RRNA 4021183 METHYLTRANSFERASE 155 GDC_MTUB_(—) 4045946 4046290 114 − chalcone/stilbene synthase 4045946 family protein 156 GDC_MTUB_(—) 4053033 4053635 200 + putative protein (2G313) 4053033 157 GDC_MTUB_(—) 4140236 4140460 74 − DNA-binding protein, CopG 4140236 family 158 GDC_MTUB_(—) 4169350 4169706 118 + PROBABLE CUTINASE 4169350 PRECURSOR CUT5 159 GDC_MTUB_(—) 4170798 4171211 137 + PUTATIVE 4170798 OXIDOREDUCTASE 160 GDC_MTUB_(—) 4252190 4252921 243 + Salivary gland secretion 1 4252190 CG3047-PA 161 GDC_MTUB_(—) 4260620 4261213 197 + SPAPB15E9.01c 4260620 162 GDC_MTUB_(—) 4302166 4302858 230 + u1764ad 4302166 163 GDC_MTUB_(—) 4317863 4318309 148 + POSSIBLE TRANSPOSASE 4317863 [SECOND PART] 164 GDC_MTUB_(—) 4341852 4342388 178 − GLP_49_64409_65443 4341852 165 GDC_MTUB_(—) 4391527 4391988 153 − AT9S 4391527 166 gi!Sars174_ref 701 1225 174 + ABC transporter ATP binding seq_OUTPUT protein/Cytochrome c oxidase F_GDC_701_(—) folding protein 1225 167 gi!Sars68_refs 1397 1603 68 + Major facilitator for eq_OUTPUTF_(—) superfamily protein or GDC_1397_(—) serine/threonine kinase 2 1603 168 gi!Sars61_refs 8828 9013 61 + Putative protein eq_OUTPUTF_(—) GDC_8828_(—) 9013 169 gi!Sars78_refs 24492 24764 90 + NADH dehydrogenase I chain eq_OUTPUTF_(—) GDC_28559_(—) 28795

A systematic sensitivity and specificity analysis of GeneDecipher has been done on 10 microbial genomes (FIG. 3). Further analysis of GeneDecipher on viral genomes is presented here.

SARS-CoV genome sequence:Sequences of the 18 SARS-CoV strains available in the GenBank database (http://www.ncbi.nlm.nih.gov/Entrez/genomes/viruses) were downloaded and analyzed. These include SARS-CoV Refseq (NC_(—)004718.3), SARS-CoV TWC(AY32118), SIN2774(AY283798), SIN2748(AY283797) SIN267{circumflex over ( )}(AY283796), SIN2677(AY283794), SIN25ti6(AY283794), Frankfurt 1 (AY291315), BJ04(AY279354) BJ03(AY278490), BJ02(AY278487), GZ01(AY278848), CUHKW1(AY278554), TOR2(AY274119), TW1(AY291451), BJ01(AY278488), Urban(AY278741), HKU-39849(AY278491). Other information related to protein coding genes was retrieved from http://www.ncbi.nlm.nih.gov/genomes/SARS/SAks.html.

Testing of GeneDecipher on Viral Genomes:

To test our method on viral genomes the applicants first analyzed Human Respiratory Syncytial Virus (HRSV), complete genome using GeneDecipher. Comparison of GeneDecipher results with state of the art method ZCURVE_CoV has been done (Table 3). ZCURVE_CoV is able to predict 8 annotated proteins out of 11 reported at NCBI without any false positives. ZCURVE_CoV was unable to predict the following three genes: PID 9629200 (location 626 . . . 1000, non-structural protein2 (NS2)); PID 9629205 (location 4690 . . . 5589, attachment glycoprotein (G)); and PID 9629208 (location 8171 . . . 8443, matrix protein 2(M2)). GeneDecipher predicted 10 out of total 11 annotated proteins of HRSV without any false positives. The gene missed by GeneDecipher was PID 9629208 (location 8171 . . . 8443, matrix protein 2) which was notably missed by ZCURVE_CoV too.

This successful prediction of protein coding regions in HRSV genome increases our confidence to predict protein coding regions on newly sequenced SARS-CoV genomes.

Analysis of SARS-CoV Using GeneDecipher:

The applicants analyzed all 18 strains of SARS-CoV using GeneDecipher. (Detailed results are available on the website given above). GeneDecipher predicts a total of 15 protein coding regions in SARS-CoV genomes including both the polyproteins 1a, 1ab (Sars2628 C-terminal end of Polyprotein 1ab), and all four known structural proteins (M, N, S, and E) for each of the 18 strains. GeneDecipher also predicts 6 to 8 additional coding regions depending on the genome sequence of the strain used. The length of these additional coding regions varied between 61 and 274 amino acids.

GeneDecipher predicts 12 coding regions which are common to all 18 strains (Table 4), and one coding region (Sars63, sars6 at NCBI refseq genome) present in 5 strains. GeneDecipher predicts gene Sars90 in GZ01 strain, and Sars154 (Sars 3b at NCBI refseq genome) in BJ02 strain specifically.

These 12 common protein coding regions consist of the 6 basic proteins of SARS-CoV (2 polyproteins and the 4 structural proteins); Sars274 (Sars3a at NCBI refseq database), Sars122 (Sars7a at NCBI refseq database), Sars78 (already reported with start shifted as ORF14/Sars9c in TOR2 strain); and three newly predicted (false positives with respect to current annotation at NCBI) protein coding regions Sars 174, Sars68, and Sars61. The three newly predicted genes lie completely within polyprotein 1a genomic region. Although our method discards such genes in bacterial genomes, possibility of finding such genes in viral genomes has not been ruled out. As these genes are present in all 18 strains it is likely that they are protein coding genes.

The applicants predict three more coding regions Sars63, Sars154, and Sars90 apart from the 12 discussed above. Sars63 is identified in 5 strains and not identified in remaining 13 strains. This coding region is already reported in NCBI refseq (Sars6). Here the applicants can not comment much about the existence of Sars63 (Sars6 at NCBI refseq) because it is identified in 5 strains and not identified in rest 13. This is due to high density of non-synonymous mutations across strains in this region. Two coding regions Sars154 (sars3b at NCBI), and Sars90 (newly predicted in GZ01 starin) are identified in only one strain. Since these two coding regions are identified in only one strain, they are less likely to be protein coding regions, as also suggested by ZCURVE_CoV (Chen et al., 2003) analysis. The locations of these three genes in different strains are provided in Table 5.

Since the peptide libraries are made from the genome sequences of various organisms, the evolutionary origin of a given protein can be traced. If the protein is rich in heptapeptides found occurring in viral genomes then that protein is considered to be of viral origin. The applicants found that 5 core proteins (two polyproteins and three structural proteins M, N, and S) are of viral origin. The remaining, including 3 new predictions, are of prokaryotic origin. It is interesting to that from the same DNA region the applicants are getting proteins in different frames which contain peptides from different origin. Here, how same DNA sequence can code for both bacterial and viral origin is intriguing. This might explain why these new protein coding genes were not detected in primary attempts based on homology to other known viral genome sequences.

Comparison with the Existing System—ZCURVE_CoV.

Comparison of GeneDecipher, ZCURVE_CoV results with the known annotations for Urbani and TOR2 strains of SARS-CoV are presented in Tables 6a and 6b.

In general, GeneDecipher results are in good agreement with the known annotations. In case of Urbani strain GeneDecipher predicts all the known genes except Sars84(X5), Sars63(X3) and Sars154(X2). Sars84(X5) and Sars63(X3) are supported by ZCURVE_CoV whereas Sars154(X2) is missed by both the methods. GeneDecipher predicts four new genes in this strain which incidentally are not supported by ZCURVE_CoV. It is noticeable that out of these four genes Sars78 is already known for strain TOR2 as ORF14/Sars9c. This supports the likelihood of the gene being present in Urbani strain. However, ZCURVE_CoV predicts 2 new genes which are not supported by GeneDecipher either.

GeneDecipher predictions for TOR2 strain are identical with those for Urbani strain. In this strain GeneDecipher predicts 9 known genes but fails to predict 6 genes with known annotations. These 6 genes are: Sars154 (ORF4), Sars98 (ORF13), Sars63 (ORF7), Sars44 (ORF9), Sars39 (ORF10), and Sars84 (ORF11). Of these, Sars154 (ORF4) and Sars98 (ORF13) are also missed by ZCURVE_CoV. It is to be noted that both Sars44 (ORF9) and Sars39 (ORF10) are ORFs very small in length (44 and 39 amino acids respectively), and their presence too is not consistent across various SARS strains. Sars63 (ORF7) has been predicted by GeneDecipher in 5 other strains but not in the two strains considered here.

Mutation Analysis:

Analysis using multiple sequence alignment (ClustalW) for 3 newly predicted protein coding genes Sars174, Sars68 and Sars61 across all 18 strains shows:

-   -   1. Sars68 has one point mutation at location 80 GAT->GGT (D->G)         SIN2677 strain.     -   2. Sars174 has two synonymous point mutations at location 204         CGA->CGC in GZ01 strain and at location 447 CTG->CTT in BJ04         strain.     -   3. Sars61 has one point mutation at location 119 CTG->CAG (L->Q)         in GZ01 strain.

These three newly predicted genes are present in all 18 strains without significant mutations and has no significant hits with BLASTP in non-redundant database. This indicates that these three proteins might have crucial biological functions specific to SARS-CoV. Therefore these coding sequences might serve as candidate drug targets against SARS.

Function Assignment:

In total the applicants predict 15 coding regions in SARS-CoV out of which functions of the four structural proteins (M, N, S and E) have already been assigned. Although the polyprotein 1ab has been assigned only replicase activity, our analysis implies that the replicase activity is associated with Sars2628 (C terminal of ORF 1ab) fragment. The complete 1ab polyprotein contains 6 functional signatures of which polyprotein 1a contains signatures associated with metabolic enzymes (Table 7a). Functions were assigned to the polyproteins on the basis of peptides (length 7 or more amino acids) occurring in proteins having similar functions in at least 5 different organisms. Other predicted genes/protein coding regions contain peptides which occur in fewer genomes. Based on these peptides the applicants suggest functions, albeit with lesser confidence (Table 7b). The biological relevance of these finding remains to be explored. TABLE 3 Comparison of GeneDecipher results with ZCURVE_CoV results on HRSV genome, with respect to annotated genes Annotated genes ZCURVE_CoV GeneDecipher Start End Length Start End Length Start End Length 99 518 139 99 518 139 99 518 139 626 1000 124 — — — 626 1000 124 1140 2315 391 1140 2315 391 1140 2315 391 2348 3073 241 2348 3073 241 2348 3073 241 3263 4033 256 3158 4033 291 3158 4033 291 4303 4500 65 4303 4500 65 4303 4500 65 4690 5589 299 — — — 4690 5589 299 5666 7390 574 5666 7390 574 5621 7390 589 7618 8205 195 7618 8205 195 7618 8205 195 8171 8443 90 — — — — — — 8509 15009 2166 8443 15009 2188 8443 15009 2188

TABLE 4 Protein coding genes predicted by GeneDecipher in SARS-CoV Refseq common to all 18 strains. S. Length No. Start Stop Frame bp aa Feature 1 265 13413 1+ 13149 4382 Sars1a polyprotein 2 701 1225 2+ 525 174 Sars174(new predic- tion) 3 1397 1603 2+ 207 68 Sars68(new predic- tion) 4 8828 9013 2+ 186 61 Sars61(new predic- tion) 5 13599 21485 3+ 7887 2628 Sars2628(C-terminal end of polyprotein lab) 6 21492 25259 3+ 3768 1255 Spike (S) protein 7 25268 26092 2+ 825 274 Sars274(Sars 3a) 8 26117 26347 2+ 231 76 Sars76(Sars4) 9 26398 27063 1+ 666 221 Sars221(Sars5) 10 27273 27641 3+ 369 122 Sars122(Sars7a) 11 28120 29388 1+ 1269 422 Sars422(Sars9a) 12 28559 28795 2+ 237 78 Sars78 (Identical to ORF 14/Sars9c in TOR2 with shifted start)

TABLE 5 Identification of Sars90, Sars63, Sars154 as protein coding genes by GeneDecipher in various strains of SARS-CoV S. Strain Sars90 (New Sars63(Sars6 Sars154(Sars No. name prediction) at NCBI) 3b at NCBI) 1 SIN2748 — — — 2 BJ01 — 27055 . . . 27246 — 3 BJ02 — 27074 . . . 27265 25689 . . . 26153 4 BJ03 — 27070 . . . 27261 — 5 BJ04 — 27058 . . . 27249 — 6 Frank- — — — furtt1 7 Urbani — — — 8 GZ01 24492 . . . 24764 27058 . . . 27249 — 9 SIN2500 — — — 10 SIN2677 — — — 11 SIN2679 — — — 12 SIN2774 — — — 13 CHUKW1 — — — 14 TW1 — — — 15 TWC — — — 16 HKU- — — — 39849 17 Refseq — — — 18 TOR2 — — —

TABLE 6(a) Comparison of GeneDecipher results with ZCURVE_CoV results on SARS-CoV genome Urbani strain, with respect to annotated genes Annotated genes ZCURVE_CoV GeneDecipher Start End Length Start End Length Start End Length Features 265 13398 4377 265 13398 4377 265 13413 4382 ORF 1a — — — — — — 701 1225 174 Sars174(New prediction by GeneDecipher) — — — — — — 1397 1603 68 Sars68(New prediction by GeneDecipher) — — — — — — 8828 9013 61 Sars61(New prediction by GeneDecipher) 13398 21485 2695 13398 21485 2695 13599 21485 2628 ORF 1b 21492 25259 1255 21492 25259 1255 21492 25259 1255 S protein 25268 26092 274 25268 26092 274 25268 26092 274 Sars274(X1) 25689 26153 154 — — — — — — Sars154(X2) 26117 26347 76 26117 26347 76 26117 26347 76 E protein 26398 27063 221 26398 27063 221 26389 27063 224 M protein 27074 27265 63 27074 27265 63 — — — Sars63(X3) 27273 27641 122 27273 27641 122 27273 27641 122 Sars122(X4) — — — 27638 27772 44 — — — Sars44 — — — 27779 27898 39 — — — Sars39 27864 28118 84 27864 28118 84 — — — Sars84(X5) 28120 29388 422 28120 29388 422 28120 29388 422 N protein — — — — — — 28559 28795 78 Sars78(Identical to ORF 14/Sars9c in TOR2 with shifted start)

TABLE 6(b) Comparison of GeneDecipher results with ZCURVE_CoV results on SARS-CoV genome TOR2 strain, with respect to annotated genes ZCURVE_CoV GeneDecipher Annotated genes predicted genes predicted genes Start End Length Start End Length Start End Length Features 265 13398 4377 265 13398 4377 265 13413 4382 ORF 1a — — — — — — 701 1225 174 Sars174(New prediction by GeneDecipher) — — — — — — 1397 1603 68 Sars68(New prediction by GeneDecipher) — — — — — — 8828 9013 61 Sars61(New prediction by GeneDecipher) 13398 21485 2695 13398 21485 2695 13599 21485 2628 ORF 1b 21492 25259 1255 21492 25259 1255 21492 25259 1255 S protein 25268 26092 274 25268 26092 274 25268 26092 274 ORF3(Sars274) 25689 26153 154 — — — — — — ORF4(Sars154) 26117 26347 76 26117 26347 76 26117 26347 76 E protein 26398 27063 221 26398 27063 221 26389 27063 224 M protein 27074 27265 63 27074 27265 63 — — — Sars63(ORF7) 27273 27641 122 27273 27641 122 27273 27641 122 Sars122(ORF8) 27638 27772 44 27638 27772 44 — — — Sars44(ORF9) 27779 27898 39 27779 27898 39 — — — Sars39(ORF10) 27864 28118 84 27864 28118 84 — — — Sars84(ORF11) 28120 29388 422 28120 29388 422 28120 29388 422 N protein 28130 28426 98 — — — — — — ORF13 28583 28795 70 — — — 28559 28795 78 Sars78(Identical to ORF 14/Sars9c in TOR2 with shifted start)

TABLE 7(a) Functional assignment of polyproteins in SARS (Urbani) Genome using PLHOST S. NCBI Conserved peptide No. annotation signature Function assigned 1 Sars1ab RIRASLPT Phosphoglycerate kinase (Poly protein1ab) RSETLLPL Sulfite reductase (NADPH), Flavoprotein beta subunit LDKLKSLL Probable acyl-CoA thiolase ATVVIGTS cell division protein ftsZ NVAITRAK DNA-binding protein, probably DNA helicase LQGPPGTGK DNA helicase related protein 2 Sars1a poly RIRASLPT Phosphoglycerate kinase protein1a RSETLLPL Sulfite reductase (NADPH), Flavoprotein beta subunit LDKLKSLL Probable acyl-CoA thiolase 3 Sars 2628 ATVVIGTS cell division protein ftsZ (C terminal of Sars1ab) NVAITRAK DNA-binding protein, probably DNA helicase LQGPPGTGK DNA helicase related protein

TABLE 7(b) Suggested functions for some of the non-structural genes in SARS-CoV using PLHOST S. Peptide No. Gene Signature Suggested function 1 Sars174(new TLSKGNAQ ABC transporter ATP prediction) binding protein [Lactococcus lactis subsp. lactis] VAQMGTLL Cytochrome c oxidase folding protein [Synechocystis sp. PCC 6803] 2 Sars68(new LVLVLILA putative major facilitator prediction) superfamily protein [Schizosaccharomyces pombe] TQTLKLDS serine/threonine kinase 2; Serine/threonine protein kinase-2 [Homo sapiens] 3* Sars90(new GLLHRGT NADH Dehydrogenase I prediction Chain only in GZ01 strain) 4 Sars61(new LLPLLAFL Putative protein prediction) (Conserved across 2 organisms) 5 Sars274(Sars3a) LLLFVTIY Polyamine transport protein; Tpo1p [Saccharomyces cerevisiae] 6 Sars154(Sars3b) QTLVLKML K550.3.p [Caenorhabditis elegans] 7 Sars63(Sars6) DDEELMEL Elongation factor Tu [Lactococcus lactis subsp. lactis] 8 Sars122(Sars7a) LIVAALVF Putative transport transmembrane protein [Sinorhizobium meliloti] RARSVSPK Src homology domain 3 [Caenorhabditis elegans] 9* Sars78(Sars9c) QLLAAVG Gamma-glutamate kinase (Conserved across 8 organisms) *No conserved octapeptide was found. However, function has been assigned on the basis of the highly conserved heptapeptide.

From the aforementioned The applicants have disclosed 4 new genes including Sars78 in SARS-CoV. The analysis further corroborates the finding of ZCURVE_CoV (Chen et al., 2003) that ORF Sars154 (listed in Refseq as Sars3b) is unlikely to be a coding region. The applicants have also assigned functions to the two polyproteins 1ab and 1a. In addition to replication associated function of C-terminal of 1ab polyprotein, the applicants' analysis implies that the polyprotein 1a may be associated with metabolic enzyme like functions. In all, six peptide signatures are present in polyprotein 1ab. The applicants have suggested putative function for other 9 proteins including ones newly predicted Ly GeneDecipher.

Advantages:

-   -   1. Main advantage of the present invention is to provide a new         method for prediction of protein coding DNA sequences without         using any external evidences like ribosome binding sites,         promoter sequences, transcription start sites or codon usage         biases.     -   2. It provides a method for statistical analysis of protein         coding DNA sequences that utilizes the biological information         retained in the conserved peptides which withstood evolutionary         pressure.     -   3. It provides a simple method for start site prediction of a         protein coding gene.     -   4. It provides a method to detect organism specific, strain         specific protein coding DNA sequences.     -   5. It provides novel protein coding DNA sequences, which could         be used as potential drug targets.

REFERENCES

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1. A computer based versatile method for identifying protein coding DNA sequences useful as drug targets said method comprising steps of: a. generating peptide libraries from the known genomes with oligopeptide of length ‘N’ computationally arranged in an alphabetical order, b. artificially translating the test genome to obtain a polypeptide in each reading frame, c. converting each polypeptide sequence into an alphanumeric sequence with one corresponding to each reading frame on the basis of occurrence of these oligopeptides in the peptide libraries, d. training Artificial Neural Network (ANN) with sigmoidal learning function to the alphanumeric sequences corresponding to known protein coding DNA sequences and known non-coding regions, e. deciphering the protein coding regions in the test genome, and f. identifying longer stretches of peptides mapped to large number of known genes serving as functional signatures.
 2. A method claimed in claim 1 wherein the artificial neural network has one or more input layer, one or more hidden layer with varying number of neurons, and one or more output layer.
 3. A method claimed in claim 1 wherein the number of neurons in the hidden layer is preferably
 30. 4. A method claimed in claim 1 wherein the value of the ‘N’ is 4 or more.
 5. A method claimed in claim 1 wherein the sigmoidal learning function has five parameters comprising total score, mean, fraction of zeroes, maximum continuous non-zero stretch, and variance.
 6. A method claimed in claim 1, wherein the method of identifying genes using oligopeptides that are found to occur in the ORFs of other genomes but not limited to genomes such as H. influenzae, M. genitalium, E. coli, B. subtilis, A. fulgidis, M. tuberculosis, T. pallidum, T. maritima, Synecho cystis, H. pylori, and SARS-CoV.
 7. A method claimed in claim 1, wherein the peptide library data may be taken from any organism but not specifically limited to those used in the invention.
 8. A set of genes of SEQ ID Nos. 1 to 44 of H. influenzae, identified by using method of claim
 1. 9. A set of proteins of SEQ ID Nos. 170 to 213 corresponding to genes of SEQ ID Nos 1 to 44 of H. influenzae, identified by using method of claim
 1. 10. A set of genes of SEQ ID Nos. 45 to 60 of H. pylori, identified by using method of claim
 1. 11. A set of proteins of SEQ ID Nos. 214 to 229 corresponding to genes of SEQ ID Nos 45 to 60 of H. pylori identified by using method of claim
 1. 12. A set of genes of SEQ ID Nos. 61 to 165 of M. tuberculosis, identified by using method of claim
 1. 13. A set of proteins of SEQ ID Nos. 230 to 334 corresponding to genes of SEQ ID Nos 61 to 165 of M. Tuberculosis, identified by using method of claim
 1. 14. A set of genes of SEQ ID Nos. 166 to 169 of SARS-corona virus identified by using method of claim 1
 15. A set of proteins of SEQ ID Nos. 335 to 338 corresponding to genes of SEQ ID Nos 166 to 169 of SARS-corona virus, identified by using method of claim
 1. 16. Use of proteins of SEQ ID Nos. 170 to 338 corresponding to the genes of SEQ ID Nos. 1 to 169, as the drug target for the managing disease conditions caused by the pathogenic organisms in a subject in need thereof.
 17. A use as claimed in claim 16, wherein the pathogenic organisms are selected from a group comprising SARS-corona virus, H. influenzae, M. tuberculosis, and H. pylori.
 18. A use as claimed in claim 16, wherein the use is extended to eukaryotes and multicellular organisms.
 19. A use as claimed in claim 16, wherein the subject is an animal.
 20. A use as claimed in claim 16, wherein the subject is a human. 